AT526050B1 - Device for measuring braking emissions - Google Patents

Abstract

The invention relates to a device (1) for measuring brake emissions (BE) with a housing (3) for holding a test object (2), in particular a brake arrangement (2). The housing (3) has a funnel-shaped feed area (7), through which cooling air (KL) for cooling the test object (2) and for detecting the brake emissions (BE) from a supply air duct (4) is fed through an inlet opening (9). the housing (3) can be introduced. The braking emissions (BE) can then be passed on from the housing (3) through an outlet opening (12) into an exhaust air duct (5) and to a measuring system. At least one perforated plate (13) is arranged in the funnel-shaped feed area (7) at a perforated plate position (P) for flow straightening of the cooling air (KL) introduced into the housing (3). The perforated plate position (P) for attaching the at least one perforated plate in the supply area (7) between the inlet opening (9) and an opening (10) to a central receiving area (6) for the test specimen (2) can be selected as desired.

Description

Description

DEVICE FOR MEASURING BRAKE EMISSIONS

TECHNICAL FIELD

The present invention relates to a device for measuring brake emissions with a housing for accommodating a test object, in particular a brake arrangement. The housing has a funnel-shaped supply area, via which cooling air for cooling the test object and for detecting the braking emissions from a supply air duct can be introduced into the housing through an inlet opening. The braking emissions can then be passed on from the housing through an outlet opening into an exhaust air duct and to a measuring system.

STATE OF THE ART

[0002] Environmental pollution with fine dust from vehicles, especially motor vehicles or trucks, has been known for a long time and is subject to increasingly strict legal regulations. To date, the focus has mainly been on fine dust pollution, which is generated by the combustion process in an internal combustion engine and enters the environment via exhaust gases. Other sources of fine dust in vehicles have now also been identified, with the brake system of a vehicle in particular being another source of fine dust. During operation of a vehicle - especially when braking in the vehicle - the brake disc and brake pads of the brake system are rubbed in such a way that the finest particles are released. This abrasion from the brake disc and brake pads enters the environment and can therefore contribute to fine dust pollution with corresponding risks of health problems.

[0003] Manufacturers of vehicles or braking systems are therefore increasingly paying attention to reducing the generation of fine dust by the braking system. In order to develop a brake system, brake test stands are often used on which the brake system is set up and subjected to dynamic tests. In order to be able to better assess the origin and extent of fine dust generation through brake emissions or the abrasion of the brake disc and brake pads, brake test benches are often expanded to be able to record and measure the brake emissions - i.e. brake abrasion. This topic has already been discussed in the specialist literature, for example in the text Kukutschova J., et al., “On airborne nano/micro-sized wear particles released from low-metallic automotive brakes”, Environmental Pollution 159 (2011), p. 998-1006. treated. The brake disc and brake pad are essentially enclosed on the brake test bench and the air in the enclosure is extracted for analysis of the brake emissions. Another example of a corresponding extension of a brake test bench is described, for example, in WO 2017/097901 A1, which shows a device for detecting and measuring brake dust particles, which was integrated into a brake test bench.

[0004] Furthermore, a device for detecting and measuring brake dust is also known from WO 2018/202421 A1, which is integrated in a brake test stand. In this device, the brake is arranged as a test specimen in an enclosed brake receiving space. An air flow is guided through the brake receiving space or its housing by means of a blower system, with a supply air duct and an exhaust air duct of the blower system being coupled to the brake receiving space. The brake holder, to which the brake is attached, is positioned so that the brake is arranged between an outlet opening of the supply air duct and a funnel-shaped inlet opening of the exhaust air duct. Furthermore, the cross sections of the supply air and exhaust air ducts are designed to be large enough so that the air flow fully covers the brake and feeds the brake emissions through the inlet opening of the exhaust air duct to the sampling device or the particle measuring device. To even out the air flow, current-carrying elements can also be arranged in the supply air duct.

Such current guiding elements or flow straighteners have been known for a long time in order to convert a flow into a flow with a known flow profile or to guide it accordingly. For example, DE 10 2014 111 585 A1 shows a test bench with a cooling gas inflow device, in which at least one flow straightener is arranged in a straight section of the supply line for a uniform cooling gas flow in a supply line through which the cooling gas flow is directed to the test object. This flow straightener is constructed, for example, from a grid of cooling gas baffles, which are arranged parallel to the straight section, and is arranged at a predetermined distance from the outlet opening of the supply line. Furthermore, the cooling gas inflow device also has cooling gas deflection plates arranged equidistantly, for example in a curved region of the supply line, in order to generate a uniform cooling gas flow. In order to apply the most uniform cooling gas flow possible to the test specimen in the receiving area, complex structures consisting of, for example, several flow baffles are usually necessary. In particular in the case of supply line areas that are not designed in a straight line, such as curves, funnel-shaped designs, etc., these must be shaped accordingly (e.g. bent, expanded, etc.) and then arranged in a complex manner in the supply line or in the supply line area in order to ensure a uniform flow of the fluid stream to reach.

PRESENTATION OF THE INVENTION

The invention is therefore based on the object of specifying a device for measuring braking emissions, in which, with an arbitrarily shaped, in particular funnel-shaped, supply area, a cooling air flow is directed evenly over a test object using very simple means and the braking emissions to be measured are reliably detected.

[0007] This object is achieved by a device according to the independent claim. Advantageous embodiments of the present invention are described in the dependent claims.

According to the invention, the problem is solved by a device for measuring brake emissions, which has a housing for accommodating a test object, in particular a brake arrangement. The housing has a funnel-shaped feed area through which cooling air from a supply air duct can be introduced into the housing through an inlet opening in order to cool the test object and to detect the braking emissions. The braking emissions can then be directed together with cooling air from the housing through an outlet opening into an exhaust air duct and on to a measuring system. In this case, at least one perforated plate is arranged at a perforated plate position in the funnel-shaped supply area for a flow straightening of the cooling air introduced into the housing, the perforated plate position for attaching the at least one perforated plate in the supply area - i.e. between the inlet opening and an opening to a central receiving area for receiving the Test item - can be chosen arbitrarily.

The main aspect of the proposed solution is that a flow straightening effect is achieved in a simple manner by at least one perforated plate arranged arbitrarily in the supply area. As a result, the cooling air introduced into the housing is ideally directed to the test object using very simple means in order to cool it efficiently. Furthermore, this ensures effective detection of the brake emissions in the receiving area of the test object in order to then forward the brake emissions together with the cooling air via the outlet opening in the housing and the exhaust air duct to the measuring system for evaluation. Elaborately and complexly designed or shaped structures made up of, for example, several flow plates in the supply area are no longer necessary in order to achieve a desired flow of cooling air.

Ideally, a diameter of the at least one perforated plate is adapted to a cross section of the funnel-shaped feed area at the selected perforated plate position. This makes it easy to create an opening area through which the cooling air can flow through the perforated plate - i.e. a number of holes, an arrangement of the holes, a hole diameter.

ser, a hole size, etc. or by a hole pattern of the perforated sheet - defined. The at least one perforated plate can, for example, have many holes with a small diameter or fewer holes with a larger diameter. Furthermore, the at least one perforated plate can have a hole pattern with holes arranged in rows or holes arranged offset in rows, the distances between the rows of holes and / or the hole diameters of the holes being designed to be constant. This means that each row of holes has, for example, holes with the same hole diameter, which are arranged at the same distance. However, it is also conceivable that the distances and/or hole diameters of the rows of holes are designed differently. For example, the distances between holes in the middle of the perforated plate can increase and/or a hole diameter can decrease, while towards the edge the distances between the holes decrease and/or the hole diameters increase. But it is also conceivable that, for example, the distances between holes in the middle of the perforated plate decrease and/or a hole diameter increases, while towards the edge the distances between the holes increase and/or the hole diameters decrease. In this way, a gradient can be applied very easily in the hole pattern in order to direct a flow of cooling air specifically towards the test object and for the detection of brake emissions.

Alternatively, an arrangement of the holes in the form of concentric circles as a hole pattern of the at least one perforated plate is also conceivable. It is also conceivable that the circularly arranged hole circles have the same design - i.e. have holes with the same diameter - and are arranged at a constant distance from one another in the perforated plate. It would also be possible to design the hole pattern in such a way that, for example, the distances between the holes and/or the hole diameters of the holes of the individual hole circles change with a distance from a central axis of the concentrically arranged hole circles. For example, the distances between holes in the middle of the perforated plate can increase and/or a hole diameter can decrease, while towards the edge the distances between the holes decrease and/or the hole diameters increase. But it is also conceivable that, for example, the distances between holes in the middle of the perforated plate decrease and/or a hole diameter increases, while towards the edge the distances between the holes increase and/or the hole diameters decrease.

An expedient embodiment of the device for measuring brake emissions provides that, in addition to the at least one perforated plate, another perforated plate for the flow straightening of the cooling air is arranged in the funnel-shaped supply line area. The at least one perforated plate and the further perforated plate can then be arranged at any selectable perforated plate positions in the feed area - i.e. between the inlet opening and an opening to a central receiving area for receiving the test specimen. Furthermore, it is also possible to arrange at least three or more perforated plates at any selectable perforated plate positions in the funnel-shaped supply line area of the housing. These two, three or more perforated sheets can differ in terms of their respective hole pattern (e.g. number of holes, hole diameter, hole pattern, etc.), as long as the same opening area through which flow is ensured is ensured.

When using at least one perforated plate, this perforated plate is expediently designed in such a way that, regardless of the selected perforated plate position at which the perforated plate is arranged in the funnel-shaped supply line area, there is a ratio between an opening area of the perforated plate through which flow can flow and a cross-sectional area of the supply line area the selected perforated sheet position has a constant value. This means, no matter at which position in the supply area the at least one perforated plate is arranged, the ratio between the flow-through opening area of the perforated plate and the cross-sectional area of the supply area at the perforated plate position of the perforated plate is always the same.

[0014] Furthermore, it is advantageous if the housing of the device for measuring braking emissions is sealed in an airtight manner. This means that the housing is appropriately sealed from the environment so that only cooling air can be introduced into the housing via the supply air duct, with the cooling air being filtered and appropriately conditioned (with

predeterminable temperature, humidity, etc.).

Ideally, the device for measuring brake emissions can be combined with a dynamic brake test bench or integrated into a dynamic brake test bench. This means that testing brake arrangements on the brake test bench can be combined very easily and efficiently with measuring and evaluating brake emissions.

BRIEF DESCRIPTION OF THE FIGURES

The present invention is explained in more detail below with reference to Figures 1 to 3, which show exemplary, schematic and non-restrictive advantageous embodiments of the invention. Show it

1 shows an embodiment of a device according to the invention for measuring brake emissions with a housing for holding a test object and a funnel-shaped supply line area and at least one perforated plate

2 shows a further embodiment of the device according to the invention for measuring braking emissions with two perforated plates

3 shows a further embodiment of the device according to the invention for measuring braking emissions with three perforated plates

4a to 4d embodiments of the at least one perforated plate

IMPLEMENTATION OF THE INVENTION

Figure 1 shows, by way of example and schematically, a device 1 for measuring brake emissions BE, which can be combined with a dynamic brake test stand or integrated into a dynamic brake test stand. For the sake of simplicity, the embodiment shown in Figure 1 was limited to that part of the device 1 for measuring brake emissions BE in which a test object 2, in particular a brake arrangement 2, is attached during a brake emissions test or in which the brake emissions BE - during the brake emissions test. i.e. abrasion on the brake discs and brake pads of the test specimen 2 - is detected by means of supplied cooling air KL. An air conditioning system in which, for example, the temperature, humidity, flow, etc. of the cooling air KL is monitored and regulated, filter units for cleaning the cooling air KL and a measuring system for measuring and evaluating the brake emissions BE (e.g. brake dust particle concentration, brake dust particle sizes, etc. ) are not shown in Figure 1.

The device 1 for measuring brake emissions BE has a housing 3 in which a test specimen 2 or a brake arrangement 2 to be tested is mounted during the brake emissions test. The housing 3 is ideally sealed in an airtight manner to prevent untreated air from penetrating and contaminating the cooling air KL flowing around the test object 2. The housing 3 is designed in such a way that the conditioned and air-conditioned cooling air KL supplied via a supply air duct 4 is directed evenly around the test object 2 or the brake arrangement 2. The brake arrangement 2 is thereby cooled by the cooling air KL. Furthermore, brake emissions BE - in particular brake dust particles that arise during the brake emissions test - are recorded by the cooling air KL and forwarded to the measuring system via an exhaust air duct 5.

For this purpose, the housing 3 has a central receiving area 6, in which the test object 2 or the brake arrangement 2 is mounted for the brake emission test. For this purpose, the test specimen 2 can, for example, be arranged on a receiving device, not shown, which carries the test specimen 2 and its components (e.g. brake discs, brake caliper with the brake pads, any brake filter devices that may be present, etc.) and ensures stable support of the braking torques during the test. The central receiving area 6 is ideally designed and dimensioned in such a way that brake arrangements 2 of different sizes can be attached for testing. A size or dimensioning can be

such as the design of the central receiving area 6 can be specified by the largest brake arrangement 2 to be tested in the device 1. The central receiving area 6 can, for example - as shown by way of example in FIG.

Furthermore, the housing 3 has a supply area 7 and a discharge area 8, which are arranged on both sides of the central receiving area 6. The supply area 7 extends from an inlet opening 9, via which the housing 2 is connected to the supply air duct 4, to an opening 10 to the central receiving area 6. Analogously, the discharge area 8 extends from an opening 11 to an outlet opening 12, via which the housing 3 is connected to the exhaust air duct 5. During the brake emission test, the cooling air KL from the conditioning system is passed through the inlet opening 9 into the housing 3 or into the supply line area 7 via the supply air duct 4. The cooling air KL flows through the supply area 7 via the opening 10 to the central receiving area 6 and thus to the test object 2. After the cooling air KL has flowed around the test object 2 or has recorded the brake emissions BE generated during the brake emissions test, the brake emissions BE mixed with the brake emissions BE Cooling air KL is directed into the discharge area 8 via the opening 11 of the central exception area 6. From there, the cooling air KL mixed with the brake emissions BE is forwarded through the outlet opening 12 into the exhaust air duct 5 and further to a removal position for the measuring system.

In order to ensure a uniform flow of the cooling air KL through the housing 3 and a corresponding mixture of the cooling air KL with the braking emissions BE in the central receiving area 6, the supply area 7 and the discharge area 8 are designed, for example, conical or trapezoidal. For example, a diameter of the inlet opening 6, which also corresponds to the diameter of the supply air duct 4, is smaller than a diameter of the opening 10 to the central receiving area 6, whereby the supply area 7 has the shape of a funnel or is designed in a funnel shape. The funnel shape of the supply area 7 is designed such that a transition from the inlet opening 6 to the opening 10 or to the central receiving area 6 is smooth and continuous - i.e. without abrupt changes in cross-sections in the course of the supply area 7. For this purpose, the inlet opening 6 can be dimensioned such that a smooth transition angle (e.g. from 15° to 30°) in the direction of the opening 10 to the central receiving area 6 is ensured.

[0026] Furthermore, the discharge area 8 can also be designed conical or trapezoidal, with the one diameter of the outlet opening 12, which also corresponds to the diameter of the exhaust air duct 5, being smaller than the opening 11 of the central receiving area 6 to the discharge area 8. This means that the discharge area 8 also has a funnel shape, which can be designed analogously to the supply region 7 without abrupt changes in cross-sections in the course of the discharge region 8. For this purpose, it can also be provided that the outlet opening 12 is dimensioned such that a smooth transition angle (e.g. 15° to 30°) in the direction of the opening 11 to the central receiving area 6 is ensured.

Ideally, the housing 3 is designed symmetrically to a horizontal axis A and to a vertical axis B of the housing 3, with the two axes A and B intersecting in the center of the central receiving area 6. That is, the funnel shape of the supply area 7 and the discharge area 8 is designed identically, with the supply area 7 and the discharge area 8 intersecting the e.g. cylindrical, central receiving area 6 in the respective opening 10, 11. Furthermore, the housing 3 is ideally aligned so that the cooling air only enters and exits in the horizontal direction - i.e. in the direction of the horizontal axis A of the housing 3.

In order to ensure that the cooling air KL flows as uniformly as possible in the housing 3 - especially in the central receiving area 6 and around the test object 2 - at least one perforated plate 13 is arranged at at least one perforated plate position P in the supply area 7. The perforated plate 13 serves to straighten the flow into the housing 7 via the inlet opening 9

introduced cooling air KL. The perforated plate position P of the at least one perforated plate 13 in the supply line area 7 can be chosen arbitrarily. For attaching the at least one perforated plate 13 in the feed area 7, at least one of the predetermined perforated plate positions P1, P2, P3 can be selected. That is, the at least one perforated plate 13 can - for example as shown in Figure 1 - be attached to any perforated plate position P, which can be in the area of the inlet opening 9 of the feed area 7 up to the area of the opening 10 to the central receiving area 6. This means, for example, a position in the area of the inlet opening 9, a position in the area of the opening 10 to the central receiving area 6 or any position in the supply area 7 in between can be selected as the perforated plate position P for the at least one perforated plate 13. Furthermore, the at least one perforated plate 13 can be provided with a filter mat 16, for example to additionally filter the cooling air KL and to increase a flow-influencing effect.

The diameter of the at least one perforated plate 13 is adapted to a respective cross section of the feed area 7 at the perforated plate position P selected in each case. This means that the closer it is to the opening 10 to the central receiving area 6, the larger the diameter of the at least one perforated plate 13. The at least one perforated plate 13 has the largest diameter at a selected perforated plate position P in the area of the opening 10 to the central receiving area 6. The perforated plate 13 has the smallest diameter at a selected perforated plate position P in the area of the inlet opening 9. The opening surface through which the cooling air KL can flow can thereby be determined by the at least one perforated plate 13 - in particular by a number of holes, an arrangement of the holes, a hole diameter, a hole size , etc. or be defined by a hole pattern of the perforated plate 13.

For this purpose, the at least one perforated plate 13 can, for example, have a larger number of holes with a smaller diameter or smaller hole size. Alternatively, for example, only a smaller number of holes with a larger diameter or larger hole size can be provided in at least one perforated plate 13.

As a hole pattern, the at least one perforated plate 13 can have, for example, holes arranged in rows, as shown by way of example in FIGS. 4a and 4b. The rows of holes can be offset from one another, for example, as shown in Figure 4b. It is also conceivable that the holes in the perforated plate 13 are arranged in the form of concentric circles, as shown by way of example in FIGS. 4c and 4d. Both with a row-like arrangement of the holes (with or without an offset of the rows) and with an arrangement of the holes in concentric circles, the distances between the rows/circles of holes can be a constant distance and all holes can have the same diameter or size.

[0032] However, it is also possible for the at least one perforated plate 13 to be designed in such a way that the distances between the rows of holes or hole circles and/or the hole diameters or sizes depending on the row of holes or hole circle are, for example, at a distance from the center of the at least one perforated plate 13 or towards the edges of the at least one perforated plate 13 (e.g. a larger distance between the holes and / or smaller holes in a central region of the perforated plate 13 and a smaller distance between the holes and / or larger holes in the edge regions of the perforated plate 13 or vice versa - i.e. a smaller distance between the holes and/or larger holes in the central region of the perforated plate 13 and a larger distance between the holes and/or smaller holes in the edge regions of the perforated plate 13). This means that a gradient is applied in the hole pattern of the at least one perforated plate 13 in order to additionally direct the flow of the cooling air KL in a desired direction. Figures 4c and 4d show exemplary embodiments for holes arranged in a circle.

Furthermore, the design of the perforated plate 13 can be adapted to the selected perforated plate position P in the supply line area 7. For this purpose, the perforated plate 13 can, for example, be designed such that a ratio of the opening area of the at least one perforated plate 13 through which the cooling air KL flows and a cross-sectional area of the funnel-shaped feed area 7 has a constant value. The relationship is with it

regardless of the selected perforated plate position P, at which the perforated plate 13 is attached in the supply line area 7, always the same. That is, regardless of whether the at least one perforated plate 13 is attached to a perforated plate position P in the vicinity of the inlet opening 9 or in the vicinity of the opening 10 to the central receiving area 6, the ratio of the surface through which flow can pass to the cross-sectional area of the supply line area 7 at the perforated plate position P remains the same.

Ideally, if necessary, additional perforated plates 13 can be arranged - staggered - in the supply area 7 in order to direct the cooling air KL evenly over the test specimen 2. The further perforated plates 13 can be provided at any perforated plate positions P in the supply line area 7. The individual perforated plates 13 arranged in the supply area 7 can differ in terms of their hole pattern - i.e. in the number of holes, arrangement of the holes, hole pattern, hole diameter used and / or hole sizes, etc. - as long as the same opening area through which flow is ensured is ensured by the respective hole pattern . Furthermore, all or only some of the attached perforated plates 13 can be provided with filter mats 16.

2 and 3 respectively show embodiments of the device 1 for measuring braking emissions BE, in which, for example, in addition to the at least one perforated plate 13, a further perforated plate 14 or a third perforated plate 15 is provided in the supply line area 7. However, the embodiments shown as examples in Figures 2 and 3 do not represent a restriction to two or three perforated plates 13, 14, 15, but are only to be seen as examples of an arrangement of more than one perforated plate 13 in the supply line area 7. Of course - if appropriate - more than three perforated plates 13, 14, 15 can also be arranged in the supply line area 7.

2 again shows the portion of the device 1 for measuring brake emissions BE, in which the test object 2 or brake arrangement 2 is mounted during a brake emissions test. That is, the housing 3 with the central receiving area 6 for receiving the test object 2, the funnel-shaped supply area 7 and the funnel-shaped discharge area 8. The embodiment of the device 1 for measuring braking emissions BE shown in FIG. 2 is next to the at least one, first perforated plate 13 a further, second perforated plate 14 is provided in the funnel-shaped supply area 7. The first perforated plate 13 is arranged at the first perforated plate position P1. The further, second perforated plate 14 is attached, for example, to the second perforated plate position P2. Both the first perforated plate position P1 and the second perforated plate position P2 in the supply line area 7 can be selected as desired. In Figure 2, the first perforated plate 13 is arranged, for example, closer to the opening 10 to the central receiving area 6 than the second perforated plate 14. As a result, the first perforated plate 13, for example, has a larger diameter than the second perforated plate 14, since both perforated plates 13, 14 are adapted to a respective cross section of the supply line area 7 at the respectively selected perforated plate position P1, P2. In order to filter the cooling air KL and to increase the flow-influencing effect, a filter mat 16 can be provided on both perforated plates 13, 14 or (as shown by way of example in FIG. 2) only on one of the two perforated plates 13, 14. But it is also conceivable that none of the two perforated plates 13, 14 has a filter mat 16. Furthermore, both perforated plates 13, 14 can differ in the hole pattern - that is, in the number of holes, arrangement of the holes, hole pattern, hole diameter used and / or hole sizes, etc. - as long as the same opening area through which flow is ensured is ensured by the respective hole pattern.

3 shows an embodiment of the device 1 for measuring brake emissions BE, in which a third perforated plate 15 is arranged in the feed area 7 in addition to a first perforated plate 13 and a further, second perforated plate 14. 3 again shows the portion of the device 1 for measuring brake emissions BE, in which the test object 2 or brake arrangement 2 is attached during a brake emissions test. That is, the housing 3 with the central receiving area 6 for receiving the test object 2, the funnel-shaped supply area 7 and the funnel-shaped discharge area 8. The first perforated plate 13 is arranged at the first perforated plate position P1. The second perforated plate 14

is arranged at the second perforated plate position P2 and the third perforated plate 15 at a third perforated plate position P3. Any position in the supply line area 7 can be selected for each of the three hole positions P1, P2, P3.

3, for example, the first perforated plate 13 is arranged closer to the opening 10 to the central receiving area 6 than the second perforated plate 14 and the third perforated plate 15. Furthermore, the selected third perforated plate position P3 of the third perforated plate 15 is located e.g. closer to the inlet opening 9 than the first perforated plate position P1 of the first perforated plate 13 and the second perforated plate position P2 of the second perforated plate 14. Since the diameters of the perforated plates 13, 14, 15 again correspond to the cross section of the supply line area 7 to the respective perforated plate position P1, P2, P3 are adapted, for example, the diameter of the first perforated plate 13 at the first perforated plate position P1 is larger than the diameter of the second perforated plate 14 at the second perforated plate position P2, which in turn is larger than the diameter of the third perforated plate 15 at the third perforated plate position P3. All three perforated plates 13, 14, 15 or only some of the perforated plates 13, 14, 15 can also be provided with filter mats 16 for filtering the cooling air KL and to increase the flow-influencing effect or flow rectification. But it is also conceivable that none of the perforated plates 13, 14, 15 has a filter mat 16. Furthermore, the three perforated plates 13, 14, 15 can differ in the hole pattern - that is, in the number of holes, arrangement of the holes, hole pattern, hole diameter used and / or hole sizes, etc. - as long as the same opening area through which flow is ensured is ensured by the respective hole pattern .

[0039] Figures 4a to 4d show exemplary embodiments of the at least one perforated plate 13 or the possible further perforated plates 14, 15; in particular, Figures 4a to 4d show examples of possible, different hole patterns that the at least one perforated plate 13 can have. In Figure 4a, for example, a row-shaped arrangement of the holes is shown as a hole pattern of the at least one perforated plate 13, the holes having the same hole size and a constant distance between the rows of holes. Furthermore, the holes in the rows of holes are arranged next to or below one another in both a horizontal and a vertical direction. Figure 4b shows a hole pattern with rows of holes offset from one another, the holes also having the same hole size and the rows of holes having a constant distance. For example, every second row of holes is offset from a previous or subsequent row of holes. This means that a hole in a row of holes lies, for example, in the vertical direction below the distance between two holes in a previous or subsequent row of holes. However, it is also conceivable that the hole size of the individual rows of holes and/or a distance between the hole rows varies in the embodiments shown in FIGS. 4a and 4b.

4c and 4d show further possible embodiments of the at least one perforated plate 13 or the associated hole pattern. The holes in the perforated plate 13 are arranged in the form of concentric circles. Even when the holes are arranged in concentric circles, the distances between the rows/circles of holes can be a constant distance and all holes can have the same diameter or size. However, it is also possible for the at least one perforated plate 13 to be designed in such a way that the distances between the hole circles change - for example, as shown in Figure 4c, with a distance to the center of the at least one perforated plate 13 becoming larger. Alternatively, the distances could also become larger towards the edges of the at least one perforated plate 13. However, a hole size of the individual hole circles can also change (e.g. or smaller holes in a central region of the perforated plate 13 and larger holes in the edge regions of the perforated plate 13 or vice versa). Furthermore, it is also conceivable that - for example as shown in Figure 4d - a hole size changes in addition to the distance between the hole circles in order to apply a gradient through the hole pattern of the at least one perforated plate 13, which additionally directs the flow of the cooling air KL in a desired direction.

REFERENCE SYMBOL LIST

1 Device for measuring brake emissions 2 Test specimen or brake arrangement

3 housings

4 supply air duct

5 exhaust duct

6 central recording area

7 funnel-shaped supply area

8 funnel-shaped drainage area

9 inlet opening

10 Opening to the central recording area

11 Opening to the discharge area

12 outlet opening

13 (first) perforated sheet

14 additional/second perforated sheet

15 third perforated plate

16 filter mat

BE brake emissions or brake dust particles KL cooling air

A horizontal axis

B vertical axis

P, P1, P2, P3 perforated sheet positions

Claims (10)

Patent claims 1. Device (1) for measuring brake emissions (BE) with a housing (3) for holding a test object (2), in particular a brake arrangement (2), the housing (3) having a funnel-shaped feed area (7). which can be introduced through an inlet opening (9) from a supply air duct (4) into the housing (3) for cooling the test object (2) and for detecting the braking emissions (BE), and the braking emissions (BE) together with the cooling air from the housing (3) through an outlet opening (12) into an exhaust air duct (5) and can be forwarded to a measuring system, characterized in that at least one perforated plate (13) for a flow straightening of the cooling air introduced into the housing (3). (KL) is arranged in the funnel-shaped supply line area (7) at a perforated plate position (P), and that the perforated plate position (P) in the supply line area (7) can be selected as desired. 2. Device (1) according to claim 1, characterized in that the at least one perforated plate (13) is provided with a filter mat (16). 3. Device (1) according to one of the preceding claims, characterized in that a diameter of the at least one perforated plate (13) is adapted to a cross section of the funnel-shaped feed area (7) to the respectively selected perforated plate position (P). 4. Device (1) according to one of the preceding claims, characterized in that the at least one perforated plate (13) has a hole pattern with holes arranged in rows or offset in rows. 5. Device (1) according to one of claims 1 to 4, characterized in that the at least one perforated plate (13) has a hole pattern with holes arranged in concentric circles. 6. Device (1) according to one of the preceding claims, characterized in that in addition to the at least one perforated plate (13), a further perforated plate (14) is provided for the flow rectification of the cooling air (KL) in the funnel-shaped feed area (7), whereby the at least one perforated plate (13) and the further perforated plate (14) can be arranged at any two perforated plate positions (P1, P2) in the feed area (7). 7. Device (1) according to one of claims 1 to 5, characterized in that at least three perforated plates (13, 14, 15) are provided for the flow rectification in the funnel-shaped supply area, the at least three perforated plates being at any three perforated plate positions (P1 , P2, P3) can be arranged in the supply line area. 8. Device (1) according to one of claims 1 to 5, characterized in that the at least one perforated plate (13) is designed such that, regardless of the selected perforated plate position (P), at which the at least one perforated plate (13) is located Supply area (7) is arranged, a ratio between a flow-through area of the at least one perforated plate (13) and a cross-sectional area of the supply area (7) at the selected perforated plate position (P) has a constant value. 9. Device (1) according to one of the preceding claims, characterized in that the housing (3) is sealed airtight. 10. Device (1) according to one of the preceding claims, characterized in that the device (1) for measuring brake emissions (BE) can be combined with a dynamic brake test bench or can be integrated into a dynamic brake test bench. 4 sheets of drawings